Apparatus for delivering metered quantities of powdered material towards a point of use

ABSTRACT

The invention concerns apparatus for delivering metered quantities of powdered material towards a point of use, the said apparatus comprising a rotor having an outer perforated shell whose perforations are adapted to receive the powdered material, the rotor also having an inner perforated shell which is mounted within the outer perforated shell, means comprising a porous filling which spaces the inner shell from the outer shell, the said means closely contacting the outer perforated shell, powder supply means arranged to supply the powdered material as the rotor rotates to the perforations in successive portions of the outer perforated shell, and a fluid conduit which is disposed within the inner perforated shell and which is, at any moment, sealed to a portion thereof which is angularly spaced from the portion of the outer perforated shell which is being supplied with powdered material from the powder supply means, means to supply the fluid conduit with a fluid which will pass through the inner perforated shell and the porous filling, the powdered material being ejected from the perforations in the outer perforated shell and delivered in metered quantities towards the point of use.

United States Patent Jackson et al.

[ 51 May 2, 1972 [72] Inventors: Albert Edward Jackson, Givernaffield Mold, Wendover', Robert Gordon Russell, 72 Nont Parc, Prestatyn, both of England [22] Filed: July 15, 1970 [21] Appl. No.: 55,077

Related US. Application Data [62] Division of Ser. No. 782,897, Dec. 11, 1968.

FOREIGN PATENTS OR APPLICATIONS 166,554 7/1921 GreatBritain... ...239/553.3 1,015,094 12/1965 GreatBritain ..302/49 Primary Examiner-Even C. Blunk Assistant Examiner-W. Scott Carson AttorneyMawhinney & Mawhinney [5 7] ABSTRACT The invention concerns apparatus for delivering metered quantities of powdered material towards a point of use, the said apparatus comprising a rotor having an outer perforated shell whose perforations are adapted to receive the powdered material, the rotor also having an inner perforated shell which is mounted within the outer perforated shell, means comprising a porous filling which spaces the inner shell from the outer shell, the said means closely contacting the outer perforated shell, powder supply means arranged to supply the powdered material as the rotor rotates to the perforations in successive portions of the outer perforated shell, and a fluid conduit which is disposed within the inner perforated shell and which is, at any moment, sealed to a portion thereof which is angularly spaced from the portion of the outer perforated shell which is being supplied with powdered material from the powder supply means, means to supply the fluid conduit with a fluid which will pass through the inner perforated shell and the porous filling, the powdered material being ejected from the perforations in the outer perforated shell and delivered in metered quantities towards the point of use.

9 Claims, 3 Drawing Figures Patented May 2, 1972 2 Sheets-Sheet l Patented May 2, 1972 3,659,751

2 Sheets-Sheet 2 F/GZ.

APPARATUS FOR DELIVERING METERED QUANTITIES F POWDERED MATERIAL TOWARDS A POINT OF USE This application is a division of application Ser. No. 782,897 filed Dec. 11, 1968.

This invention concerns apparatus for delivering metered quantities of powdered material towards a point of use, and although the invention is not so restricted, it is more particularly concerned with apparatus for coating a surface of a moving steel strip with metered quantities of metal powders (e.g. aluminium, nickel, or chromium powders) for subsequent compaction and sintering thereon.

According to the present invention, there is provided apparatus for delivering metered quantities of powdered material towards a point of use, the said apparatus comprising a rotor having an outer perforated shell whose perforations are adapted to receive the powdered material, the rotor also having an inner perforated shell which is mounted within the outer perforated shell and is spaced therefrom by means comprising a porous filling, the said means closely contacting the outer perforated shell, powder supply means which, as the rotor rotates, are arranged to supply the powdered material to the perforation in successive portions of the outer perforated shell, and a fluid conduit which is disposed within the inner perforated shell and which is, at any moment, sealed to a portion thereof which is angularly spaced from the portion of the outer perforated shell which is being supplied with powdered material from the powder supply means, the fluid conduit being adapted to be supplied with a fluid which will pass through the inner perforated shell and the porous filling to eject the powdered material from the perforations in the outer perforated shell and so deliver metered quantities of the powdered material towards the point of use.

As will be appreciated, the outer perforated shell closely contacts the portion of the rotor which is disposed immediately radially inwardly of it, this being desirable to prevent the powdered material from passing therebetween. Moreover, if, as is preferably the case, the fluid conduit is non-rotatable, the inner perforated shell being in bearing contact therewith, then the perforations of the inner perforated shell may easily be made of such size that any smearing of the inner perforated shell by the fluid conduit will not be such as to occlude these perforations.

The porous filling preferably fills an annular space between two perforated or porous flexible sleeves which are respectively disposed in contact with the inner surface of the outer perforated shell and the outer surface of the inner perforated shell.

Sand is preferably employed to constitute the porous filling.

Alternatively, felt may be employed to constitute the porous filling.

The flexible sleeves may be formed of synthetic resin material, while each of the said shells may be a metallic shell.

A movable portion of the fluid conduit may be urged into bearing contact with the inner perforated shell, the said movable portion of the fluid conduit being connected to a fixed portion thereof by a flexible portion.

The invention also comprises apparatus as set forth above when used to deposit a coating of the powdered material onto a moving strip.

The invention is illustrated, merely by way of example, in the accompanying drawings, in which:

FIG. 1 is a diagrammatic sectional view of an apparatus according to the present invention,

FIG. 2 is a broken-away sectional view, on a larger scale, of part of the structure shown in FIG. 1, and

FIG. 3 is a section taken on the line 3-3 of FIG. I.

Referring to the drawings, an apparatus for delivering a powdered metal or alloy onto a moving steel strip comprises a rotor 11 one end of which is drivingly mounted on a drive shaft 12, the drive shaft 12 being rotatably mounted in a bush 13 carried by an upright frame member 14 of an earthed support frame 15.

The end of the rotor 11 remote from the drive shaft 12 is rotatably mounted on a bush 16, the bush 16 being mounted on a stationary rod 17. One end of the rod 17 is mounted in an upright frame member 18 of the frame 15 and is secured thereto by studs 19, the opposite end of the rod 17 being mounted in a bush 20 which is received within a recess of a boss 21 at the end of the rotor 11 adjacent the drive shaft 12.

The drive shaft 12 is driven by an electric motor 22 through a gear box 23 and clutch 24.

The rotor 11 has circular end walls 25, 26 between which is bolted a fluid-permeable curved wall structure 27. The curved wall structure 27, as best seen in FIG. 2, comprises annular end wall members 28 which support an outer perforated metallic shell 29 having perforations 30 and an inner perforated metallic shell 31 having perforations 32.

The outer perforated shell and the inner perforated shell 31 are radially spaced apart to provide an annular space therebetween in which are disposed radially spaced apart porous flexible nylon sleeves 33, 34. The sleeves 33, 34 may have a porosity of approximately 5 microns if the apparatus is to be used for delivery powders having a particle size of about 5 microns. However, if powders of larger particle size are being dealt with, the sleeves 33, 34 may be perforated rather than porous.

The sleeves 33, 34 are respectively disposed in contact with the inner surface of the outer perforated shell 29 and the outer surface of the inner perforated shell 31. The annular space between the sleeves 33, 34 is filled by pouring a sand filling 35 thereinto, the sand filling 35, which constitutes a porous filling, being compacted by vibration and physical pressure so as to stretch the sleeve 33 into intimate contact with the outer perforated shell 29, and the sleeve 34 into intimate contact with the inner perforated shell 31. Prior to such compaction of the sand filling 35, however, the diameters of the sleeves 33, 34 may differ by, say, one-fourth inch from those of the respective shells, 29, 31.

lternatively, a porous felt filling can be provided instead of the sand filling. A strip of felt is cut so as to lie as a helix around the outer surface of the sleeve 34. The felt strip is wrapped tightly around the inner sleeve 34 with its ends anchored and the outer sleeve 33 is stretched thereover. The ends of the felt strip are then released, and the strip expands radially to force the sleeves 33, 34 into intimate contact with the outer and inner shells 29, 31 respectively.

A hopper 36, or other powder supply means, Which may contain a powdered metal or alloy 37, e. g., powdered aluminium, nickel, or ferrochrome, has an outlet 38 which bears directly against, or is closely spaced from, the outer perforated shell 29. Thus, as the rotor 11 rotates counterclockwise, as indicated by the arrow 39, the powdered metal or alloy 37 will be supplied to the perforations 30 in successive portions of the outer perforated shell 29. The perforations 30 will thus act as pockets in the outer periphery of the rotor II, the pockets being adapted to receive the powdered metal or alloy from the hopper 36.

The rod 17 has an axially extending passage 44 therein whose outer end communicates with a fixed air (or other gas) conduit 45, which is adapted to be supplied with compressed air (by means not shown). Mounted on the rod 17 are axially spaced apart frame members 46 each of which is provided with a radially extending slot 47, an elongated block 48 being slidably mounted in the slots 47.

The block 48, which is mounted immediately radially inwardly of the inner perforated shell 31, is urged radially outwardly towards the latter by springs 50.

The block 48 is provided at its radially outer side with radially movable sealing members 51 which are urged by the springs 50 to bear against the internal surface of the inner perforated shell 31. The sealing members 51 define with the block 48 and the internal surface of the inner perforated shell 31 a space 52 which is supplied with air from the fixed air conduit 45 by way of the passage 44, a flexible conduit 53, and a passage 54 through the block 48.

Thus the stationary air conduit constituted by the parts 45, 44, 53, 54, 52 is, at any moment, sealed to the portion of the inner perforated shell 31 which is angularly spaced from the portion of the outer perforated shell 29 which is, at that moment, being supplied with powdered metal or alloy 37 from the hopper 36.

As will be appreciated, the air flowing radially outwardly through the said air conduit will pass through the perforations 32 in the inner perforated shell 31, and thence through the sleeve 34, the sand filling 35, and the sleeve 33, so as to pass out through the perforations 30 in the outer perforated shell 29. As a result, the powdered metal or alloy 37 in the perforations 30 which are radially aligned at any moment with the space 52 will be dispensed therefrom and ejected radially outwardly towards the substrate constituted by the moving steel strip 10, and will thus coat the adjacent surface thereof.

The moving steel strip is earthed by reason of being supported by earthed support rolls 55 (only one shown), while the rotor 1 l is earthed by reason of its being supported by, and not insulated from, the earthed frame 15.

Between the moving steel strip 10 and the rotor l 1 are two electrically conduction screens 56, 57 both of which are mounted on insulating supports 60 carried by the frame 15. The screens 56, 57 are spaced from each other and are also spaced from both the rotor 1 1 and the moving steel strip 10, so that the powdered metal or alloy which passes from the rotor 11 to the moving steel strip 10 passes successively through the screens 56, 57.

The screen 57, which is thus nearer to the moving steel strip 10, may be disposed substantially midway between the latter and the rotor 11, e.g., 2% inches from each. The screen 56, which is nearer to the rotor 11, may be substantially nearer to the latter than to the other screen 57; for example, the screen 56 may be one-half inch from the rotor 11 and 2 inches from the screen 57.

The screen 57 is connected, as indicated diagrammatically by the cable 61, to means (not shown) which electrostatically charge it with a positive or negative potential, e.g., of at least Kv. The screen 56, however, is electrically isolated but, in operation, has a potential induced in it. Thus if the screen 57 is charged at Kv, the induced charge on the screen 56 may be 10 Kv.

As a result of this arrangement, the electrostatic forces assist the air in depositing the powdered metal or alloy onto the moving steel strip 10, and thus diminish the amount of air pressure which it is necessary to use. In consequence, the amount of powdered metal or alloy lost to the atmosphere is reduced, while at the same time there will also be a reduction in the amount of air-borne dust deposited on the moving steel strip 10.

It has been found advantageous to preheat the air supplied to the conduit 45 to about 40 C., particularly when powdered aluminium is used. It is though that agglomerates break up more easily in the electrostatic field when the powder is warm.

The powdered metal or alloy which is so deposited on the strip 10 is subsequently compacted and sintered, by means not shown.

Since the inner shell 31 is a perforated, as opposed to a porous shell, the perforations 32 therein may easily be made of such size that there need be no danger of any smear-ing" caused by the bearing contact between the sealing members 51 and the inner perforated shell 31. If, on the other hand, such smearing" were to occur, there would be occlusion of the passage of the air through the perforations 32. Moreover, the inner perforated shell 31 may be made of a metal which can be machined to form a suitable bearing surface.

Additionally, the use of flexible sleeves 33, 34, with the sand filling 35 therebetween, ensures that these sleeves may be brought into intimate contact with the shells 29, 31 so that powdered metal or alloy from the hopper 36 will not be able to pass between the sleeve 33 and the outer perforated shell 29.

We claim:

1. Apparatus for delivering metered quantities of powdered material towards a point of use, the said apparatus comprising a porous rotor having an outer perforated shell whose Rerforations are adapted to receive the powdered material, t e rotor also having an inner perforated shell which is mounted within the outer perforated shell, porous means comprising a porous filling which spaces the inner shell from the outer shell, the said porous means closely contacting the outer perforated shell, powder supply means arranged to supply the powdered material as the rotor rotates to the perforations in successive portions of the outer perforated shell, and a non-rotatable fluid conduit which is in bearing contact with the inner perforated shell, the fluid conduit being disposed radially inwardly of the inner perforated shell and being, at any moment, sealed to a portion thereof which is angularly spaced from the portion of the outer perforated shell which is being supplied with powdered material from the powder supply means, and means to supply the fluid conduit with a fluid which will pass through the inner perforated shell and the porous filling, the powdered material being ejected from the perforations in the outer perforated shell and delivered in metered quantities towards the point of use.

2. Apparatus as claimed in claim 1 comprising two porous flexible sleeves which are respectively disposed in contact with the inner surface of the outer perforated shell and the outer surface of the inner perforated shell, and which define an annular space which is filled by the porous filling.

3. Apparatus as claimed in claim 2 in which sand is employed to constitute the porous filling.

4. Apparatus as claimed in claim 2 wherein felt is to constitute the porous filling.

5. Apparatus as claimed in claim 2 wherein the flexible sleeves are formed of synthetic resin material.

6. Apparatus as claimed in claim 1 wherein each of the said shells is a metallic shell.

7. Apparatus as claimed in claim 1 wherein the fluid conduit is non-rotatable, the inner perforated shell being in bearing contact therewith.

8. Apparatus as claimed in claim 7 wherein the fluid conduit has a fixed portion and a radially movable portion, means being provided to urge the radially movable portion into hear ing contact with the inner perforated shell, a flexible portion of the conduit connecting the said movable portion to the fixed portion.

9. Apparatus as claimed in claim 1 when used to deposit a coating of the powdered material onto a moving strip.

employed 

1. Apparatus for delivering metered quantities of powdered material towards a point of use, the said apparatus comprising a porous rotor having an outer perforated shell whose perforations are adapted to receive the powdered material, the rotor also having an inner perforated shell which is mounted within the outer perforated shell, porous means comprising a porous filling which spaces the inner shell from the outer shell, the said porous means closely contacting the outer perforated shell, powder supply means arranged to supply the powdered material as the rotor rotates to the perforations in successive portions of the outer perforated shell, and a non-rotatable fluid conduit which is in bearing contact with the inner perforated shell, the fluid conduit being disposed radially inwardly of the inner perforated shell and being, at any moment, sealed to a portion thereof which is angularly spaced from the portion of the outer perforated shell which is being supplied with powdered material from the powder supply means, and means to supply the fluid conduit with a fluid which will pass through the inner perforated shell and the porous filling, the powdered material being ejected from the perforations in the outer perforated shell and delivered in metered quantities towards the point of use.
 2. Apparatus as claimed in claim 1 comprising two porous flexible sleeves which are respectively disposed in contact with the inner surface of the outer perforated shell and the outer surface of the inner perforated shell, and which define an annular space which is filled by the porous filling.
 3. Apparatus as claimed in claim 2 in which sand is employed to constitute the porous filling.
 4. Apparatus as claimed in claim 2 wherein felt is employed to constitute the porous filling.
 5. Apparatus as claimed in claim 2 wherein the flexible sleeves are formeD of synthetic resin material.
 6. Apparatus as claimed in claim 1 wherein each of the said shells is a metallic shell.
 7. Apparatus as claimed in claim 1 wherein the fluid conduit is non-rotatable, the inner perforated shell being in bearing contact therewith.
 8. Apparatus as claimed in claim 7 wherein the fluid conduit has a fixed portion and a radially movable portion, means being provided to urge the radially movable portion into bearing contact with the inner perforated shell, a flexible portion of the conduit connecting the said movable portion to the fixed portion.
 9. Apparatus as claimed in claim 1 when used to deposit a coating of the powdered material onto a moving strip. 